Electronic fuel injection control for an internal combustion engine

ABSTRACT

An electronic fuel injection control includes a main control circuit which controls fuel flow to the engine by controlling the duration of pulses applied to fuel valves. In addition there is a transient fuel varying control including a differentiating circuit which differentiates the signal from a throttle position transducer. This differentiator controls a variable frequency clock which forms part of the main fuel control so that the pulse duration is lengthened or shortened for a given value of the engine parameter which controls the main fuel control according to the rate of increase or decrease of the throttle position signal.

This is a continuation of co-pending application Ser. No. 847,511 filed Nov. 1, 1977 and now abandoned.

This invention relates to an electronic fuel injection control for an internal combustion engine.

An electronic fuel injection control in accordance with the invention comprises a main control circuit sensitive to the value of at least one engine operating parameter and arranged to control the rate at which fuel is injected as a function of said parameter, means for generating an electrical demand signal (which may also be used as said control parameter) and a transient fuel varying control circuit sensitive to the rate of change of said demand signal and arranged to increase or decrease the rate of fuel delivery to the engine according to the sign and magnitude of the rate of change of said demand signal.

The demand signal may be a signal derived from a transducer mechanically coupled to a control pedal for the engine, e.g. the pedal which opens and closes the air intake throttle valve in a normal automobile engine installation. Alternatively the demand signal may be a signal derived from an air pressure transducer in the engine air intake downstream of the throttle, or from an air flow transducer in the air intake.

It will be appreciated that the transient fuel varying control circuit is sensitive only to the rate of change of the demand signal and not to the steady state value of the demand signal so that the steady value of the demand signal has no effect on the fuel delivery rate via the transient fuel varying control circuit, although it may, of course, have a direct effect on the main control circuit.

Where the main control circuit is a digital circuit in which fuel control is effected by opening an injector valve for a time dependent on the time taken for a clock pulse generator to produce a number of pulses computed by a computation circuit in accordance with the value of said control parameter, the transient fuel varying control circuit may be arranged to increase or decrease the value of the frequency of the clock pulse generator according to the magnitude and sign of the rate of change of the demand signal.

The transient fuel varying control circuit may also include means sensitive to the engine temperature for varying the magnitude of the increase or decrease in fuel supplied for a given rate of change of said demand signal.

In the accompanying drawings:

FIG. 1 is a schematic diagram illustrating one example of an electronic fuel injection control in accordance with the invention;

FIG. 2 is a circuit diagram of a part of the control shown in FIG. 1;

FIG. 3 is the circuit diagram of a temperature transducer circuit and a temperature "window" circuit forming part of the control of FIG. 1;

FIG. 4 is the circuit diagram of a clock pulse generator forming part of the control of FIG. 1;

FIGS. 5, 6, 7 and 8 are fragmentary circuit diagrams illustrating four possible modifications to the circuit shown in FIG. 2 and

FIG. 9 is a graph illustrating the relationship between the clock pulse generator output frequency and the engin water temperature achieved in the example of the invention shown in FIGS. 1 to 4.

Referring firstly to FIG. 1 the overall system comprises a main digital fuel control 10 of known type utilizing digital computation techniques to produce a digital fuel demand signal in accordance with the value or values of one or more engine operating parameters selected from air intake mass flow, engine speed, air intake manifold pressure, air intake throttle position. Such parameter or parameters is or are measured by one or more transducers 11. The digital fuel demand signal is generated by means of a read only memory matrix incorporated in the control 10 which produces a multi-bit digital output signal in accordance with the value or values of digital signals addressing the matrix and derived from the transducer or transducers. The multi-bit digital signal may be used in either of two equivalent ways. Firstly, it may be transferred to a presettable counter which is then clocked to zero or it may be applied, if need be via a latch, to one input of a digital comparator whilst the output of a counter being clocked up from zero is applied to the other input of the comparator. In either case the digital signal is transformed to a pulse duration directly proportional to the digital signal and inversely proportional to the clock frequency. FIG. 1 shows a clock pulse-generator 12 which provides the clock pulses and a fuel injector control 13 which receives the pulse duration modulated signals from the main fuel control 10.

The control 13 has two output terminals to which the pulse modulated signals from the control 10 are alternately steered, each output stage of the control 13 including an open collector power transistor (not shown). These output stages are connected to two groups of solenoids 16 forming part of a bank of fuel injection valves.

FIG. 1 illustrates a number of arrangements by means of which the clock pulse frequency is varied, both as a function of engine water temperature and as a function of the rate of movement of an accelerator pedal 17. The pedal 17 is linked to the slider of a potentiometer 18, which slider is connected by a buffer input stage 19 to an operational amplifier differentiating circuit 20, via a capacitor C₂ (which forms a part of the differentiating circuit). The circuit has clamping feedback circuits 21 and 22 which operate respectively in acceleration and deceleration. A water temperature "window" circuit 23 controls a sensitivity switch 24 through the intermediary of which the output of the differentiating circuit 20 is applied to the clock 12 and also controls a time law circuit 29 at the input to the differentiating circuit 20. The "window" circuit 23 receives an input from a temperature transducer circuit 25, which also provides an input to the clock 12.

FIG. 1 also shows an "extra pulse" circuit 26 which is triggered by the acceleration clamping circuit 21, but which is muted for a predetermined time after a deceleration has been demanded by an input from the deceleration clamping circuit 22. The circuit 26 has an open collector output stage connected by parallel diodes 27, 28 to the solenoids 16 as will be explained in more detail hereinafter.

Turning now to FIG. 2 the potentiometer 18 is connected in series with a diode D₁ between a regulated voltage supply rail 30 and an earth rail 31. The slider of the potentiometer 18 is connected via a resistor R₁ and a capacitor C₁ in series to the rail 31. The common point of the resistor R₁ and capacitor C₁ at which there appears a filtered d.c. signal corresponding to the position of the slider of the potentiometer 18 is connected both to a terminal E (see also FIG. 4) and to the base of a pnp transistor Q₁ connected as an emitter follower buffer with its collector grounded to rail 31 and its emitter connected by a resistor R₂ to the rail 30.

The emitter of the transistor is connected by a time-law switch circuit to one side of a capacitor C₂ which forms the input of the differentiating circuit 20. The time law switching circuit comprises two resistors R₃, R₄ in series between the emitter of the transistor Q₁ and the capacitor C₂ with the resistor R₃ of larger ohmic value bridged by the collector-emitter of an npn transistor Q₂ which has its base connected by a resistor R₅ to a terminal D, (see also FIG. 3). A diode D₂ has its anode connected to the common point of the resistor R₄ and the capacitor C₂ and its cathode connected to the emitter of the transistor Q₁.

The other side of the capacitor C₂ is connected by a resistor R₆ to the inverting input terminal of an operational amplifier A₁, the non-inverting input terminal of which is connected to the common point of two resistors R₇, R₈ connected in series between the rails 30, 31. Feedback around the amplifier A₁ is provided by the parallel combination of a resistor R₉ and a capacitor C₃. The main differentiating action of the amplifier is provided the capacitor C₂ and the resistor R₉ which dominate the transfer function of the amplifier for low frequency signals. The resistors R₆ and capacitor C₃ provide an integral action at high frequency to overcome the differential action so that the transfer function at high frequencies is integral rather than differential. This eliminates or at least substantially reduces the effect of high frequency noise and interference on the differentiating circuit.

The acceleration and deceleration clamping circuits share a common biasing chain R₁₀, R₁₁ and R₁₂ connected in series between the rails 30, 31. The common point of the resistors R₁₁ and R₁₂ is connected to the cathode of a diode D₃ with its anode connected to the base of an npn transistor Q₃ which has its collector connected to said other side of the capacitor C₂ and its emitter connected by a resistor R₁₃ to the emitter of pnp transistor Q₄ having its collector connected to the rail 31 by a resistor R₁₄. The base of the transistor Q₄ is connected by a resistor R₁₅ to the rail 31 and is also connected to the cathode of a diode D₄ which has its anode connected to the output terminal of the amplifier A₁.

The common point of the resisitors R₁₀ and R₁₁ is connected by two diodes D₅, D₆ in series to the base of a pnp transistor Q₅, the collector of which is connected to said other side of the capacitor C₂. The emitter of the transistor Q₅ is connected by a resistor R₁₆ to the emitter of an npn transistor Q₆ the collector of which is connected by a resistor R₁₇ to the rail 30. The base of the transistor Q₆ is connected directly to the output terminal of the amplifier A₁.

The bases of the transistors Q₃, Q₅ are interconnected by a resistor R₁₈.

In steady state conditions the output terminal of the amplifier A₁ will be at a voltage set by the resistors R₇ and R₈. This will set the voltage at the base of the transistor Q₄ higher than the voltage at the base of the transistor Q₃ so that neither of these will conduct and similarly the transistors Q₅, Q₆ will be off.

During acceleration the output of the amplifier A₁ falls to a level determined by the rate of increase of the voltage at the slider of the potentiometer 18. Should this output voltage fall to a level lower than that at the junction of the resistors R₁₁ and R₁₂, the transistors Q₃ and Q₄ will both turn on, diverting sufficient current from the capacitor C₂ to hold the amplifier output constant. When the increase in input voltage ceases capacitor C₂ can change through the resistor R₄ and the transistor Q₂ (assuming this to be conductive) and the amplifier output returns to its previous voltage at a rate determined by such charging. If the transistor Q₂ is not conductive, the inclusion of the resistor R₃ in the charge path of the capacitor C₂ has the effect delaying the release of clamping and also increasing the duration of charging.

In deceleration, the output of the amplifier A₁ increases and eventually turns on transistor Q₅ and Q₆ to provide the clamping action, when the voltage at the base of transistor Q₁ ceases to fall the capacitor C₂ discharges rapidly via the diode D₂ irrespectively of whether the transistor Q₂ is conductive or not.

The diodes D₃ and D₄ are included to compensate for the base-emitter voltages of the transistors Q₃ and Q₄ so that no temperature drift effects occur. Similarly the base-emitter voltages of the transistors Q₅ and Q₆ are compensated for by the diodes D₅ and D₆.

The output terminal of the amplifier A₁ is connected to the rail 30 by two resistors R₁₉, R₂₀ in series and to an output terminal A by a resistor R₂₁, pnp transistor Q₇ has its emitter connected to the common point of the resistors R₁₉ and R₂₀, its collector connected to the terminal A and its base connected by a resistor R₂₃ to the terminal D. The transistor Q₇ constitutes the sensitivity switch 24 of FIG. 1. As will be explained hereinafter the terminal A is held at a fixed voltage such that the amplifier A₁ draws current from terminal A via the resistor R₂₁. When transistor Q₇ is on the resistors R₁₉, R₂₀ are arranged to draw no current from terminal A when the signal output is steady, but the overall gain of the circuit is increased--i.e. the current drawn by the amplifier A₁ from the terminal A increases for a given rate of increase of the input signal from the accelerator pedal potentiometer 18.

FIG. 2 also shows the extra pulse circuit 26. This is constituted by a transistor Q₈ with its emitter grounded to the rail 31 and its collector connected by two resistors R₂₄, R₂₅ in series to the rail 30. The junction of the resistor R₂₄, R₂₅ is connected by two resistors R₂₆, R₂₇ in series to the rail 31 and by a resistor R₂₈ to the inverting input terminal of a voltage comparator A₂, a diode D₇ bridging the resistor R₂₈ and a capacitor C₄ connecting the collector of the transistor Q₈ to the inverting input terminal of the comparator A₂. The non-inverting input terminal of the comparator A₂ is connected by a resistor R₂₉ to the junction of the resistors R₂₆, R₂₇. The non-inverting input terminal is also connected by a resistor R₃₀ to a terminal C' (see FIG. 3). The output terminal of the comparator A₂ is connected by a resistor R₃₁ to the rail 30 and by two resistors R₃₂, R₃₃ in series to the rail 31. The common point of the resistors R₃₂, R₃₃ is connected to the base of a transistor Q₉, the emitter of which is grounded to the rail 31 and the collector of which is connected to the cathodes of the diodes 27, 28.

When the transistor Q₄ turns on as the acceleration clamping level is reached current flows in resistor R₁₄ flows until at some point the transistor Q₈ turns on. This reduces the voltage at the junction of the resistor R₂₄ and the capacitor C₄. Initially, however, capacitor C₄ draws current through the resistor R₂₈ and thus causes the output of the comparator A₂ to go high until the capacitor C₄ is charged to a given level. The transistor Q₉ conducts for the duration of this pulse, causing an additional injection action from all the injectors simultaneously. When the transistors Q₄ and Q₈ turn off again the diode D₇ allows rapid discharge of the capacitor C₄, and limits the voltage excursion of the inverting input terminal of the comparator A₂.

For muting the extra pulse circuit just described an npn transistor Q₁₀ has its emitter connected to the rail 31 and its collector connected to the non-inverting input terminal of the comparator A₂. The base of the transistor Q₁₀ is connected to the common point of two resistors R₃₄ and R₃₅ connected in series between the rail 31 and the collector of a pnp transistor Q₁₁. The base of Q₁₁ is connected to the collector of the transistor Q₆ and its emitter is connected to the rail 30. A capacitor C₅ is connected between the base and collector of the transistor Q₁₁.

When the transistor Q₆ turns on as the deceleration clamping level is reached, the transistor Q₁₁ turns on at a predetermined higher level set by the resistor R₁₇ thereby turning on transistor Q₁₀ and grounding the non-inverting input terminal of the comparator A₂. The transistor Q₁₁ does not turn off immediately the transistor Q₆ turns off because the capacitor C₅ continues to supply base current to the transistor Q₁₁ for a predetermined period, thereby preventing operation of the extra pulse circuit for a predetermined time after a "clamping level" deceleration has taken place. This muting arrangement comes into play when rapid pedal movements are executed such as during gear changing or during repeated acceleration of an unloaded engine prior to pulling away from rest.

The temperature dependent circuit of FIG. 3 includes a thermistor R₄₀ sensitive to the engine cooling water temperature. The thermistor R₄₀ is connected between the base of a pnp transistor Q₁₂ and the rail 31 in parallel with a resistor R₄₁, a resistor R₄₂ being connected between such base and the rail 30. The collector of the transistor Q₁₂ is connected to the rail 31 and its emitter is connected by a resistor R₄₃ to the rail 30, and is also connected to a terminal C and to the anode of a diode D₈ with its cathode connected by a resistor R₈₅ to the rail 31 and also connected to the terminal C'. The cathode of the diode D₈ is also connected via a resistor R₄₄ to the inverting input terminal of a voltage comparators A₃, a further resistor R₄₅ connecting this input terminal to the inverting input terminal of a further voltage comparator A₄. The non-inverting input terminals of the comparators A₃ and A₄ are connected to the common points of three resistors R₄₆, R₄₇ and R₄₈ connected in series between the rails 30 and 31 so that the non-inverting input terminal of the comparator A₃ is at a higher voltage than that of comparator A₄. Positive feedback resistors R₄₉, R₅₀ connect the output terminals of the two comparators A₃, A₄ to their non-inverting input terminals so as to provide a small amount of hysteresis to prevent spurious triggering of the comparator. The output terminal of the comparator A₃ is connected to the inverting input terminal of the comparator A₄ and a load resistor R₅₁ is connected between the rail 30 and the output terminal of the comparator A₄ which is connected to the terminal D.

The voltage at the terminal C falls substantially linearly over the normal working range of the system. At low temperatures (e.g. below 15° C.) the output of the comparator A₃ is low and that of the comparator A₄ is therefore high. As the temperature rises and the voltage at terminal C falls, the comparator A₃ switches so that the output of the comparator A₄ goes low. As the temperature continues to rise the comparator A₄ switches (at about 60° C.) and its output goes high again.

Turning now to FIG. 4, the clock pulse generator includes a pnp transistor Q₁₃ with its base at a fixed voltage (of about 3.3 V) and its collector connected by a capacitor C₆ to the rail 31. The emitter of the transistor Q₁₃ is connected by a resistor R₅₂ to the rail 30 and is also connected to the terminal A. The terminal C of FIG. 3 is also arranged to provide an input to the clock circuit to vary the proportion of the current in resistor R₅₂ which enters the emitter of the transistor Q₁₃. The terminal C is connected to the base of two npn transistors Q₁₇ and Q₁₈ which have their collectors connected to the emitter of the transistor Q₁₃. The emitter of the transistor Q₁₇ is connected to the common point of two resistors R₈₆ and R₈₇ connected in series between the rails 30, 31. Similarly the emitter of the transistor Q₁₅ is connected to the common point of two resistors R₈₈, R₈₉ connected in series between the rails 30, 31. The resistors R₈₆ to R₈₉ are chosen so that the transistor's Q₁₇, Q₁₈ switch off at different voltage levels of terminal C. Thus the current drawn by the transistors Q₁₇, Q₁₈ will decrease with increasing temperature, initially at a relatively steep slope until the transistor Q₁₇ turns off and then at a shallow slope until transistor Q₁₈ turns off. At higher temperatures the current drawn through the resistor R₅₂ is not temperature dependent. The collector of the transistor Q₁₃ is connected to the non-inverting input terminal of a comparator A₅ which has a load resistor R₅₄ connected between its output terminal and the rail 30. The inverting input terminal of the comparator A₅ is connected by a resistor to the common point of two resistors R₅₅, R₅₆ connected in series between the rails 30 and 31. The output terminal of the comparator A₅ is connected to the base of an npn transistor Q₁₄ the emitter of which is connected by a resistor R₅₈ to the rail 31 and the collector of which is connected to the inverting input terminal of the comparator A₅. A second npn transistor Q₁₅ has its base connected to the emitter of the transistor Q₁₄, its emitter grounded to the rail 31 and its collector connected so the non-inverting input terminal of the comparator A₅. Because of the fixed voltage bias on the base of the transistor Q₁₃ its emitter is held at a fixed voltage (about 4 V) and the current passing through the resistor R₅₂ is constant. A very small amount of this current passes through the base-emitter junction of the transistor Q₁₃ and variable amounts are sunk via the terminal A and via the transistors Q₁₇ and Q₁₈ depending on the conditions in the FIG. 1 circuit and the temperature respectively. The remaining current passes into the capacitor C₆ charging it linearly whenever the transistor Q₁₅ is off. This occurs whenever the output of the comparator A₅ is low so that the voltage at the non-inverting input terminal of the comparator rises linearly until it exceeds the voltage set at the inverting input terminal. The output of the comparator A₅ now goes high turning on both transistors Q₁₄ and Q₁₅. The transistors Q₁₄ causes the voltage at the inverting input terminal to be reduced by drawing current through to resistors R₅₅ and R₅₇ , thereby increasing the speed of switching and the transistor Q₁₅ discharges the capacitor C₆, rapidly. The comparator A₅ then switches back to its original state and the cycle re-starts. For a fixed voltage at the junction of the resistors R₅₅, R₅₆ the frequency of the clock is proportional to the capacitor C₆ charging current.

The voltage at the junction of resistors R₅₅ and R₅₆ is not, however constant because of the effect of the components shown at the left hand side of FIG. 4. These components include a voltage comparator A₆ which has its non-inverting input terminal connected by a resistor R₆₀ to the terminal E (of FIG. 2) and its inverting input terminal connected to the common point of two resistors R₆₁, R₆₂ connected in series between the rail 31 and the cathode of a diode D₉ the anode of which is connected to the rail 30. The comparator A₆ has positive feedback from its output terminal to its non-inverting input terminal via a resistor R₆₃ and a further resistor R₆₄ connects the non-inverting input terminal to the rail 31. A resistor R₆₅ connects the output terminal of the comparator A₆ to the rail 30 and a resistor R₆₆ connects this output terminal to the junction of the resistors R₅₅ and R₅₆.

The comparator A₆ is set so that its output is normally low but goes high when the accelerator pedal is nearly fully depressed. This causes an increase in the voltage at the junction of the resistors R₅₅ and R₅₆ and therefore decreases the clock frequency and increases the quantity of fuel injected for a given fuel demand signal.

In addition two resistors R₆₇ and R₆₈ are connected in series between the rail 30 and the junction of the resistors R₅₅ and R₅₆. These normally increase the voltage at the junction of R₅₅ and R₅₆ slightly, but a terminal F at the junction of the resistors R₆₇ and R₆₈ is provided and can be grounded whenever it is intended that the vehicle in which the fuel injection control is installed is to be used predominatly at high attitudes. This increases the clock frequency and reduces the fuel injected.

Turning now to FIG. 9, the graph shows the overall effect of temperature on the clock frequency. The line A is the steady state frequency curve and the lines B and C show the limits of frequency variation resulting from clamping of the differentiating circuit in acceleration and deceleration respectively.

Below 15° C. and above 60° C. the transistor Q₇ is off because the output of the comparator A₄ which controls it is high. Relatively narrow limits of acceleration enrichment and deceleration enleanment are then permitted. In between 15° C. and 60° C. the output of the comparator A₄ goes low turning on the transistor Q₇ and the overall gain of the differentiator (considered as a current sink) increases.

In the modification shown in FIG. 5 gain variation with temperature is obtained by switching in and out an additional resistor R₇₀ in parallel with the resistor R₉. This is effected by means of an npn transistor Q₁₆ with its collector connected by the resistor R₇₀ to the inverting input terminal of the amplifier A₁ and its emitter connected to the output terminal of the amplifier A₁. A bias resistor R₇₁ is connected between the base and emitter of the transistor Q₁₆ to bias it off and a diode D₁₀ and a resistor R₆₉ in series connect the base of the transistor to the terminal D to turn the transistor Q₁₆ on at extreme temperatures and thereby reduce the gain of the differentiating circuit.

The modification shown in FIG. 6 affects the time law switch based on transistor Q₂. Instead of varying a resistance in series with the capacitor C₂, the transistor Q₂ now introduces a capacitor C₇ and resistor R₇₂ in series with one another across the capacitor C₂. This not only changes the time constants in the manner required but also varies the gain of the differentiator so that the transistor Q₇ of FIG. 2 can be omitted completely. The diode D₂ must also be emitted so that time law variations apply to acceleration and deceleration clamping.

The modification shown in FIG. 7 includes a quite different form of arrangement for varying the effect of the differentiation on the clock frequency with temperature. In this case the output of the amplifier A₁ is connected by a resistor R₇₃ to the common point of a pair of resistors R₇₄ and R₇₅ connected in series between the rails 30 and 31. The emitter of a transistor Q₁₇ is connected to this same common point, the collector of this transistor being connected to the terminal A and its base being connected by a resistor R₇₆ to the terminal C. This modification can be used in conjunction with the modifications shown in FIGS. 5 and 6 which give gain variation by alteration of feedback or by alteration of the input capacitance of the differentiating circuit.

Turning finally to FIG. 8 a different arrangement is shown for determining the clamping threshold levels. In this case separate potential dividers are used for biasing the acceleration and deceleration clamp circuits. The resistors R₈₀ and R₈₁ connected in series between the rails 30 and 31 have their common point connected to the cathode of the diode D₃. Two further resistors R₈₂ and R₈₃ connected in series between the rails 30, 31 have their common point connected to the anode of the diode D₅. The terminal D is connected to the cathode of a diode D₁₂ with its anode connected to the common point of the resistors R₈₀ and R₈₁ so that only the acceleration clamping threshold is altered when the signal at D goes low. 

We claim:
 1. An electronic fuel injection control comprising a main control circuit sensitive to the value of at least one engine operating parameter and arranged to control the rate at which fuel is injected as a function of said parameter, means for generating an electrical demand signal, and an electronic differentiating circuit sensitive to the rate of change of said demand signal and arranged to increase or decrease the rate of fuel delivery to the engine according to the sign and magnitude of the rate of change of said demand signal, said differentiating circuit comprising an operational amplifier connected to operate in inverting mode and having an input capacitor and a feedback resistor, and clamping circuits for limiting the excursion of the output of the operational amplifier in both senses, each clamping circuit including a first transistor, a bias circuit imposing a bias voltage on the base of said first transistor, the collector of said first transistor being connected to divert some of the current flowing through the input capacitor so that such current does not flow through the feedback resistor, and a second transistor having its collector-emitter path connected between the emitter of said first transistor and a supply conductor and its base connected to an output terminal of said operational amplifier, whereby said first and second transistors turn on when the operational amplifier output terminal reaches a set voltage determined by said bias circuit so as to divert sufficient capacitor current to maintain the operational amplifier output terminal at said set voltage.
 2. An electronic fuel injection control as claimed in claim 1, in which the input capacitor is connected to the means for generating an electrical demand signal via a time constant circuit including resistor means and a diode in parallel whereby during acceleration the associated clamping circuit remains operative after the rate of change of the demand signal has fallen below a level corresponding to said set voltage for that clamping circuit for a time dependent on the ohmic value of said resistor means, whereas in deceleration said diode conducts when the rate of change of the demand signal rises above a level corresponding to the said set voltage for the associated clamping circuit, to permit rapid release of that clamping circuit.
 3. An electronic fuel injection control as claimed in claim 2, including means sensitive to engine temperature for varying the ohmic value of said resistance means.
 4. An electronic fuel injection control as claimed in claim 3, in which said resistance means comprises first and second resistors in series and a transistor having its collector-emitter connected across said first resistor, the base of said transistor being connected to said means sensitive to engine temperature.
 5. An electric fuel injection control as claimed in claim 1, in which said main control circuit is a digital circuit incorporating a computation circuit arranged to generate periodically a multi-bit digital signal in accordance with said control parameter, a clock pulse generator and means for producing a fuel valve opening pulse of duration dependent on the time taken for the clock pulse generator to produce a number of pulses determined by said multi-bit digital signal, said clock pulse generator being a variable frequency pulse generator having a control terminal and said electronic differentiating circuit being connected to said control terminal so as to increase or decrease the frequency of the clock pulse generator according to the magnitude and sign of the rate of change of the demand signal.
 6. An electronic fuel injection control as claimed in any one of claims 1 to 5 further comprising means sensitive to the engine temperature for varying the magnitude of the increase or decrease in fuel supplied to the engine for a given rate of change of said demand signal.
 7. An electronic fuel injection control as claimed in claim 6, in which said engine temperature sensitive means comprises a temperature transducer and a temperature "window" detector producing an output when the temperature is between prescribed limits and in which said electronic differentiating circuit includes a sensitivity switch circuit connected to said detector.
 8. An electronic fuel injection control as claimed in claim 1, in which the means for generating said electrical demand signal comprises a transducer mechanically coupled to a control pedal for the engine. 